For the following two problems, does the integral diverge or converge (if so, to what)

Integral of sinx/(cosx - 1) from -pi/2 to pi/2

Integral of e^x/x from 1 to infinity

Thanks!

Apr 9th 2009, 09:09 PM

Jhevon

Quote:

Originally Posted by rainbowkaine

For the following two problems, does the integral diverge or converge (if so, to what)

Integral of sinx/(cosx - 1) from -pi/2 to pi/2

Hint: this is an odd function integratd over a balanced interval

Quote:

Integral of e^x/x from 1 to infinity

consider a slightly different problem: does the sum converge? what can you say about our integral if it does (or doesn't)

Apr 9th 2009, 09:11 PM

rainbowkaine

I don't remember. I have not taken Calculus 2 in a while and need this for a friend. An answer would be wonderful. (But my guess is that it diverges since the sum from 1 to infinity of 1/n diverges and e^n/n is larger than that)

Apr 9th 2009, 09:18 PM

Jhevon

Quote:

Originally Posted by rainbowkaine

I don't remember. I have not taken Calculus 2 in a while and need this for a friend. An answer would be wonderful. (But my guess is that it diverges since the sum from 1 to infinity of 1/n diverges and e^n/n is larger than that)

yes, good. it does diverge, but it is easier than using the comparison test, maybe. note that , so that the sum diverges by the test for divergence. so now, what can we say about our integral?

Apr 9th 2009, 09:21 PM

rainbowkaine

So this integral diverges. So do you basically evaluate the given function taking into account the limits and then whatever happens to it happens to the area under the function?

Also, for the first problem, do you tell that it's odd simply by plugging in a test value? And then once you know it's odd, what does it mean that its evaluated over a symmetric interval (I have to be able to explain this tomorrow). Thanks so much for the help!

Apr 9th 2009, 09:27 PM

Jhevon

Quote:

Originally Posted by rainbowkaine

So this integral diverges. So do you basically evaluate the given function taking into account the limits and then whatever happens to it happens to the area under the function?

yes. at first i was trying to piggy back on the integral test, but i realize that is not applicable here, since we have an increasing function. thus, we can use an argument similar to what you just gave. the integral gives the net area under the curve, and we have a curve that is diverging to infinity, exponentially so; thus, the area under the curve (and hence the integral) will diverge as well.

Quote:

Also, for the first problem, do you tell that it's odd simply by plugging in a test value? And then once you know it's odd, what does it mean that its evaluated over a symmetric interval (I have to be able to explain this tomorrow). Thanks so much for the help!

a function is odd, if . when we integrate an odd function over a balanced interval, we get zero. you can look up why this is. the basic intuitive argument is that, again, the integral gives the net area under the curve. an odd function is symmetric about the origin, and so, our function is the same on both sides of the y-axis, except one side is flipped over and thus gives the "negative" area/integral of the other side. and they cancel out